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Reionization

Reionization. The End of the Universe. How will the Universe end? Is this the only Universe? What, if anything, will exist after the Universe ends? . Some say the world will end in fire, Some say in ice. From what I’ve tasted of desire I hold with those who favor fire.

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Reionization

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  1. Reionization

  2. The End of the Universe How will the Universe end? Is this the only Universe? What, if anything, will exist after the Universe ends?

  3. Some say the world will end in fire, Some say in ice. From what I’ve tasted of desire I hold with those who favor fire. But if I had to perish twice, I think I know enough of hate To know that for destruction ice is also great And would suffice. Robert Frost

  4. Universe started out very hot (Big Bang), then expanded: How it ends depends on the geometry of the Universe:

  5. The Geometry of Curved Space Possibilities: 1) Space curves back on itself (like a sphere). "Positive" curvature. Sum of the Angles > 180

  6. 2) More like a saddle than a sphere, with curvature in the opposite sense in different dimensions: "negative" curvature. Sum of the Angles < 180 3) A more familiar flat geometry. Sum of the Angles = 180

  7. The Geometry of the Universe determines its fate

  8. Case 1: high density Universe, spacetime is positively curved Result is “Big Crunch” Fire

  9. Cases 2 or 3: open Universe (flat or negatively curved) Current measurements favor an open Universe Result is infinite expansion Ice

  10. The Five Ages of the Universe 1) The Primordial Era 2) The Stelliferous Era 3) The Degenerate Era 4) The Black Hole Era 5) The Dark Era

  11. 1. The Primordial Era: 10-50 - 105 y Something triggers the Creation of the Universe at t=0

  12. The Early Universe Inflation A problem with microwave background: Microwave background reaches us from all directions. Temperature of background in opposite directions nearly identical. Yet even light hasn't had time to travel from A to B (only A to Earth), so A can know nothing about conditions at B, and vice versa. So why are A and B almost identical? This is “horizon problem”.

  13. Solution: Inflation. Theories of the early universe predict that it went through a phase of rapid expansion. Separation between two points (m) If true, would imply that points that are too far apart now were once much closer, and had time to communicate with each other and equalize their temperatures.

  14. Inflation also predicts universe has flat geometry: Microwave background observations seem to suggest that this is true.

  15. What drove Inflation? • State change of the Vacuum • Vacuum has energy fluctuations, Heisenberg uncertainty principle states: • dE dt > h/2

  16. Clicker Question: What is the temperature of the microwave background now, 14 billion years after the Big Bang that produced it? A: 0.27 K B: 2.7 K C: 27 K D: 270 K

  17. Clicker Question: What is the fate of a closed, high density Universe? A: Can’t get started, no Big-Bang is possible. B: It expands forever C: It expands for a while, stops, then contracts to a “Big Crunch” D: It oscillates between expansion and contraction.

  18. Clicker Question: Suppose you create a perfect vacuum. Will there be anything inside it? A: No, just empty space. B: Yes, virtual particles will briefly appear and then disappear

  19. 2. The Stelliferous Era: 106 - 1014 y Now = 13 billion years ~ 1010 y

  20. How Long do Stars Live? A star on Main Sequence has fusion of H to He in its core. How fast depends on mass of H available and rate of fusion. Mass of H in core depends on mass of star. Fusion rate is related to luminosity (fusion reactions make the radiation energy). So, mass of star luminosity mass of core fusion rate lifetime   Because luminosity  (mass) 3, mass (mass) 3 1 (mass) 2 or lifetime  So if the Sun's lifetime is 10 billion years, the smallest 0.1 MSun star's lifetime is 1 trillion years.

  21. How Long do Galaxies Live? Only as long as they can continue to manufacture stars. To do that the galaxy needs gas. So, 10 billion years (for MW) Mass of gas star formation rate lifetime   Galaxies with modest star formation rates can shine for perhaps 1 trillion years

  22. 3. The Degenerate Era: 1015 - 1039 y Most stars leave behind a white dwarf Mass between 0.1 and 1.4 M_sun

  23. The Degenerate Era: 1015 - 1039 y Some failed protostars never got hot enough to ignite hydrogen fusion: Brown Dwarfs Mass < 0.08 M_sun Brown dwarf collisions can create occasional warm spots in an increasingly cool universe

  24. The Degenerate Era: 1015 - 1039 y

  25. The Degenerate Era: 1015 - 1039 y Neutron stars: Cold and no longer pulsating Mass ~ 1.5 M_sun

  26. The Degenerate Era: 1015 - 1039 y Supermassive black holes Black holes Stellar mass black holes

  27. Galaxy evolution: dynamic relaxation during the Degenerate Era Galaxies continue to merge to form large meta-galaxies (entire local group merges into a single galaxy) Massive remnants sink to the center of the galaxy Less massive remnants get ejected from the galaxy (all the brown dwarfs are gone by 1020 y).

  28. What happens to Solar systems like ours? Inner planets are fried during end of stelliferous era Planets are gradually stripped away during stellar encounters in the degenerate era 1017 1015 1012 y

  29. Dark Matter Annihlation of WIMPs (Weakly Interacting Massive Particles) - In the halo of the galaxy - In the cores of white dwarfs (power ~ 1015 Watts, 10-9 L_sun) Surface temperature ~60 K Steady energy source for ~1020 y

  30. Proton Decay Predicted lifetime of protons (and neutrons) is 1037 y - In white dwarfs (power ~ 400 Watts, 10-22 L_sun) Surface temperature ~0.06 K Composition changes to frozen H Star expands Slow decay over ~1039 y Eventual disintegration into photons Neutron stars, planets, dust, all face the same fate.

  31. 4. The Black Hole Era: 1040 - 10100 y Black holes inherit the Universe - mostly in the form of stellar mass black holes Some electrons, positrons, neutrinos and other particles remain Planets, Stars and Galaxies are all long gone

  32. 4. The Black Hole Era: 1040 - 10100 y Black holes eventually start to decay by Hawking Radiation

  33. Hawking radiation continued: Effective Temperature ~ 1/mass Universe cools with time, so that after 1021 y, the Universe is cooler than a 1 solar mass black hole (10-7 K) After 1035 y, even 1 billion solar mass black holes have begun to evaporate. Final stage of black hole radiation is explosive with 106 kg of mass converted into energy After 10100 y, even the most massive black holes are gone.

  34. 5. The Dark Era: > 10101 y Only some elementary particles and ultra-long-wavelength photons remain inside a vastly expanded Universe. Density is unimaginably low. Our observable Universe now has a size of 1078 cubic meters. In the Dark Era there will be one electron every 10182 cubic meters. Heat death - nothing happens, no more sources of energy available Or ….

  35. 1. The Primordial Era: 10-50 - 105 y Something triggers the Creation of a child Universe

  36. Child Universe Living on borrowed energy: mc2 = 1/2 m vesc2 Energy of expansion is about equal to energy in matter

  37. Clicker Question: How will the Earth be destroyed? A: Evaporated by the Sun when it becomes a Red Giant in 5 billion years. B: Blown to bits by a nearby supernova. C: Stripped away from the Sun by an encounter with another star in 1015 years. D: Blown to bits by silly humans with atomic bombs.

  38. Clicker Question: Which of the following particles can live forever (assuming it never encounters its anti-particle)? A: proton B: neutron C: electron D: He atom

  39. Clicker Question: Assuming that there were no further interactions with other galaxies, what part of our galaxy would survive for the longest time? A: our Sun and other stars like it B: brown dwarf stars C: white dwarf stars D: the supermassive black hole at the center

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